A method of enabling operation of an ignition system for outdoor power equipment may include monitoring status of a plurality of switches associated with respective components of the equipment where at least one of the respective components corresponds to one or more binary start fault operators, and setting a start enabling status for the one or more 5 binary start fault operators responsive to actuation of a start fault clearance operator.

The disclosure relates to the control of plants by means of electrical energy and the mechanical removal of parts of the plants. The disclosure relates to a method and a device for the control of undesired plants by electrical and mechanical means.

The disclosure relates to the control of plants by means of electrical energy and the mechanical removal of parts of the plants. The disclosure relates to a method and a device for the control of undesired plants by electrical and mechanical means.

A riding lawn care vehicle may include a rear discharge and a bagging attachment. The rear discharge may be disposed at a rear of the riding lawn care vehicle. The bagging attachment may be configured to attach to the rear of the riding lawn care vehicle to receive debris discharged via the rear discharge. The bagging attachment may include an adjustable member that is accessible by an operator external to the bagging attachment to enable adjustment of a pivot point of the bagging attachment relative to the rear of the riding lawn care vehicle.

A riding lawn care vehicle may include a rear discharge and a bagging attachment. The rear discharge may be disposed at a rear of the riding lawn care vehicle. The bagging attachment may be configured to attach to the rear of the riding lawn care vehicle to receive debris discharged via the rear discharge. The bagging attachment may include an adjustable member that is accessible by an operator external to the bagging attachment to enable adjustment of a pivot point of the bagging attachment relative to the rear of the riding lawn care vehicle.

A lawn mower grass catcher having a monocoque container which is downwardly tapered from the rear end of the container to its front end, the rear end being open and larger in size than the front end. A front wall closes off the front end. A single continuous sheet of material forms a flat top wall, a curved side wall, and a flat bottom wall. The curved side wall is configured as a series of adjacently aligned, frustrum shape segments. This side wall extends downward from the top wall which is fixedly attached directly to the front wall and a flat side wall. The curved side wall is fixedly attached directly to the front wall and the bottom wall. The container of the grass catcher has a plurality of hole patterns. These hole patterns, in combination with the unique shape of the container, facilitate air flow through the grass catcher and thus the flow of loose grass clippings through and into the grass catcher.

A plant by plant harvester is provided. The harvester may harvest and analyze single or double rows of crops. The single row harvester may have a first and a second guide unit which surrounds a single row of a crop and directs the single row of the crop into a sheller, picker, or grain/fruit separation unit. In an alternative embodiment of the device, the device may harvest two rows of crops. A GPS or any other location positioning device having an antenna is secured to the top of the main frame and allows the harvester to be remotely controlled. A hopper, container or holding bin may, in real-time, calculate the weight of the separated products. A plurality of sensors may be located on or near the first and/or second guide unit which allows the harvester to, for example, capture data related to the crop at the single plant level.

A lawn mower includes a drive source for driving a cutter blade, flaps, a grass clippings container, a grass clippings container weight detection unit, a travel distance detection unit, and a control unit. The control unit determines a change amount of weight of the grass clippings container detected by the grass clippings container weight detection unit over the elapsed time period from the time when detection of travel distance of the lawn mower is started by the travel distance detection unit to the time when travel of predetermined distance is completed, and implements control in a manner that the rotation speed of the drive source and the flap angle of the flaps are adjusted in accordance with the change amount of the weight.

A lawn mower includes a housing, a drive source, flaps, a grass clippings container, a grass clippings container weight detection unit, an internal pressure detection unit, and a control unit. If it is determined that a first condition where a change amount per predetermined fixed time of the weight detected by the grass clippings container weight detection unit is below a weight change amount reference value and a second condition where a change amount per predetermined fixed time of the internal pressure detected by the internal pressure detection unit has increased to a internal pressure change amount reference value, are satisfied, the control unit implements control to place the flaps in a substantially horizontal state.

A lawn mower includes a drive source for driving a cutter blade through a rotation shaft, a flap provided for the cutter blade in a manner that the flaps have a flap angle changeable along a horizontal line which is perpendicular to the rotation shaft, an actuator for controlling the flap angle of the flaps, a control unit for controlling the actuator, and a blade switching unit for switching the cutter blade between an operation state and a stop state. When the control unit determines that a stop switch signal has been received from the blade switching unit, the control unit controls the actuator to increase the flap angle of the flaps.